CH701313A2 - Timber construction element or structural element for use as leaf for e.g. inner door on building, has lamella elements provided with lamellas or narrow longitudinal slots, where slots and box form multiple of closed air chambers - Google Patents

Abstract

The element (19) has air slots extending in a longitudinal direction, and lamella elements (8) provided at a box (37) or a box-type closed wall structural element (19). The lamella elements are provided with lamellas (32) or narrow longitudinal slots (35, 36) that are arranged in a mutual manner. The slots and the box form multiple of closed air chambers (40). The lamella elements exhibit a vertical direction in a door leaf. The air chambers exhibit a rectangular shaped cross section. The lamella elements exhibits width that ranges between 4 to 15 cm, and length that ranges between 0.4 to 5 m.

Description

The invention relates to a timber element or structural element with inserted lamellar element for the area of windows and doors, with a plurality in the longitudinal direction extending louvers.

In the past, the opinion prevailed that a solid building material or solid components, in particular of wood, apart from the weight everywhere have the better properties over combined or composite structural elements. This has long been assumed in terms of thermal insulation. In recent years, semi-finished products have increasingly been developed as multilayer structures, which have been able to assert themselves in many fields of application. Both in terms of the stability of the timber component as well as on the thermal insulation, sound insulation, etc. was previously the thickness of a plate a first criterion. Only recently have new approaches been taken with composite structures which, not least thanks to the latest production means with highest production speeds, have low-cost better properties and sufficient stability for the relevant application.

In the following reference is made to DE 10 027 462, which proposes a heat-insulating timber component, in particular frame shells for windows or doors. Correspondingly, DE 10 027 462 states that in the field of energy-efficient houses and low-energy houses, or passive houses, all elements which influence the heat loss from the interior of the house to the surroundings must be optimized with regard to the heat permeability. In this case, both the outer walls, or the facade structures as well as the doors and windows are designed so that the heat loss is minimized.

A window comprises in a large part of the cases a sash and a floor frame, the floor frame is fixed on the building side and holds the wing frame pivotally majority. In a closed window, the sash is positively against the floor frame. The heat flow across the window or frame plane through the casement, through the floor frame and overlapping areas of both frames should be minimal. Because the heat-insulating property depends mainly on the thickness and the material of the frame parts or frame frame, the heat insulation could be increased by increasing the thickness of the frame frame with a selected frame material. However, the external appearance of windows or doors sets the enlargement of the leg cross-section of the floor and wing frame comparatively narrow limits. The same applies to windows without casement.

DE 10 027 462 is based on a thermally insulating timber component, in particular frame edge, which extends along a longitudinal axis and in a first direction transverse thereto has a reduced heat transfer coefficient. It is proposed that in the timber component at least one closed, slot-shaped cavity (13) is formed, which extends along the longitudinal direction and extends perpendicular to the first direction.

From DE 19 916 218 and DE 19 904 963 solutions are known, according to which the heat transfer can be reduced without increasing the leg cross-section. In these solutions, a heat-insulating strip and a heat-insulating mat are arranged in a recess on a leg or frame frame with a cover profile in the area covered by the cover profile. The resulting frames thus comprise at least three different materials. The complicated structure and the fact that a large separation effort arises for a sensible disposal are disadvantages of these solutions. It goes without saying that doors have similar problems with the windows. Even if there is no sash that can be opened, the girder remains, which can be constructed from heat-insulating timber components.

The invention has been based on the object to develop a timber component for the window and door sector, which allows to achieve thermal insulation values, which come in the field of multiple glazing, and ensure a low U or K value, easy constructed and ecologically meaningful disposable with little effort. In addition, its life should be as large as possible without drop in insulation values and stability.

The inventive timber component is characterized by a box or a box-like, closed structural element and at least one inserted therein lamellar element with thin lamellae and mutually arranged narrow slots, which together and with the box form a plurality of closed air chambers.

The inventor has recognized that windows, as well as interior and exterior doors still significant improvements are possible. The goal was in the area: the windows and exterior doors to improve the thermal insulation as well as soundproofing, and in the area of interior doors, especially the apartment doors at low demands a light weight and also to improve the stability.

The investigations have shown that with the new invention, these objectives are achieved and thus the task can be solved primarily by the full use of Lammellenelemente with a variety of closed chambers. The narrow air chambers have the shape of a rectangle, wherein the narrow side of the rectangle is preferably arranged transversely to the direction of insulation, so that a maximum number of heat and sound insulation jumps arise.

The invention allows a number of particularly advantageous embodiments, it will be made to the claims 2 to 12 reference. The invention opens up two new approaches. The first solution mainly concerns door leaves for interior doors. Here, the question of thermal insulation is usually subordinate. Central is the weight of the finished door as well as the mechanical stability of the door with respect to the prevention of long-term warping of the door, e.g. when the humidity inside and outside is different. The special here is that a plurality of lamellar elements between an inner shell and an outer shell are glued. The inner and outer shell can be formed in one or two layers. To increase stability, the lamellar elements can be aligned vertically or horizontally.

According to a second embodiment, the structural element with inserted lamellar elements should achieve the best possible heat transmission coefficient. For this purpose, the individual closed air chambers have an approximately rectangular or acute-angled cross-section, wherein the shorter dimension of the rectangular shape is aligned in the Hauptwärmedämmrichtung and with the plurality of air chambers in the thermal insulation direction results in a high thermal insulation effect.

A preferred application is that the structural element is designed as a door or window frame with comprehensive frame elements or as a window frame widening with fitted lamellar elements.

In the concrete embodiment, arise when used as a thermal insulation element in the thermal insulation direction, e.g. 6-10 or more individual self-contained air chambers, for each lamellar element through which the heat flow must pass. The air chambers, since they are formed as narrow as possible in the heat flow direction, have almost no internal air circulation, so that the heat loss is minimized. The concept of the new wooden construction element can be designed for a door or window frame, with four comprehensive frame elements with fitted lamella elements. Furthermore, it can be designed as a window sash frame, with four comprehensive frame elements, each with fitted lamellar elements.

The new thermal insulation concept not only allows optimal thermal insulation of a single narrow structural element, but in the multiple application of the lamellar elements in the closed door area as a door leaf or heat insulation sheet and / or form as cream elements, each with fitted lamellar elements. The lamellar elements fitted in the structural elements can be glued in and together have a high stability, with a thermal conductivity approximately corresponding to a multiple glazing.

The new Lammelenelement has a plurality of parallel in wood fiber longitudinal direction to the wide edges and extending on both sides arranged rectangular or acute-angled grooves or louvers, wherein the mutually arranged grooves are mutually offset, so that a short lamellar element with the forming Variety of thin slats, which are externally connected via webs, hand organ-like easily deformable. The new fin element is not stable at least in the transverse direction. The stability is achieved only by a surrounding plate or a surrounding frame profile. The grooves and lamellae form prior to installation of the lamellar elements in opposite directions open louvers, each two adjacent lamellae are connected by outer web edges and the grooves as far as they are milled, extend within the web edges over the entire thickness of the lamellar elements, so that the open slots perpendicular to the "Handorgelrichtung» are compressed until the removal of the slots to one or both open slot sides. This applies at least to short lamella element patterns.

Most preferably, the grooves of a lamellar element are made in a single pass through bilateral engagement with a composite of circular saw blades according to the number and pitch of the grooves in a milling process. This allows a very efficient production of the individual fin elements.

The lamellar elements are preferably made of wood and have a width of 4 cm to 20 cm, more preferably in the range between 5 cm and 15 cm and a length of about 0.4 m to 5 m. In this case, the lamellar element may have a back element at least on one side. The thickness of a lamellar element is in accordance with the thickness of the original board between 1 cm and 5 cm or even higher.

According to a further embodiment, the slats of the lamellar element have a thickness which corresponds approximately to the thickness (d) of the corresponding longitudinal slots or louvers, wherein the thickness (d) of the lamellae and the corresponding louver approximately 1- 5 mm is preferably 1-3 mm.

As a result, the new invention will be explained in more detail. Show it: FIG. 1 shows a vertical section of a window frame with a wall element as the lower area of the window frame, FIG. Fig. 2: <sep> a horizontal section or cutout of another embodiment of a window with window frames mounted on a wall element; Fig. 3 is a vertical section through a sash, the upper and lower wall members having fitted Lammellenelemente; Fig. 4: <sep> a building corner, with a window indicated on the bottom left; FIGS. 5a and 5b show two slat elements in perspective view; Fig. 6: <sep> seen four examples of concrete fin elements frontally; 7a, FIGS. 8a and 7b show a vertical section of a door leaf 7a with a single-ply shell and FIG. 7b with a two-ply shell. FIGS. 8a and 8b show a horizontal section of a door leaf 8a with a single-layer shell and FIG. 8b with a two-layer shell. FIGS. 9a and 9b show a side view and FIG. 9b a perspective view of a frame widening; FIG. 10 shows a detail of a window frame with frame widening; FIG. Fig. 11 <sep> a section through a window and sash, wherein also in the edges lamellar elements are glued.

In the following, reference is made to FIG. In the upper part of a window frame 1 is shown with double glazing 2. A weather strip 3 with a sealing profile 4 seals the window sash 5 against the ingress of air and water into the building interior 6. In the lower part of the picture, a window wall 7 is covered on both sides with wood with a plurality of sipe elements 8. In the example according to FIG. 1, only the window wall has sipe elements 8 for thermal insulation. The inner wall is paneled in one layer. The outer wall has a board sheathing.

Fig. 2 shows another example of the installation of inventive heat-insulating timber components. In the upper part of the picture (right) a window 9 is shown in which a single lamella element 8 is fitted. A frame frame 10 is divided in two into an inner frame part 11 and an outer frame part 12. The window frame 13 is likewise divided into two, with an inner window frame part 15 and an outer window frame part 14. The window frame 13 is struck against a wall structure element 16 and is sealed (reference 18). both with respect to the wall structure element 16 and with respect to a support bar 17. In the window frame 13, three fin elements 8 are fitted. In frame frame 10, a lamellar element 8 is fitted, wherein the lamellar elements 8 are arranged in all four frame shells 10. The large number of air chambers is designated 40.

Fig. 3 shows a window sash 20, without the installation of lamellar elements. By contrast, the upper window wall part 21 and the lower window wall part 22 are provided with lamellar elements 8. According to FIG. 1, these are windows with double glazing. The edges 50 have no lamellar elements.

FIGS. 1 to 3 show the use of the thermal insulation according to the invention for window construction. Recent developments have shown that the window frames, whether in wood, plastic or metal, are the weak point in building facades in terms of thermal insulation. Depending on the material of which the window frame is made, the lamination elements are introduced into structural elements 19 in terms of production technology. The same applies to the sash frame or for the wing shrouds and the frame shells.

Fig. 4 illustrates a wall corner, which was built from wall structure elements 19 according to the prior art. On the inside 25 installations and a plaster base 30 are attached. On the outside of a wall paper 28 and a Stulpschalung 27 is attached. With the arrows 29, the thermal insulation direction is indicated.

In the following reference is made to Figs. 5a and 5b. FIG. 5a shows a lamellar element 8 with lamellae 32 in a perspective view. Longitudinal slots 35, 36 were produced by milling, which are shown from both sides according to arrow 33 by means of indicated Fräsblatt 33. This results in a plurality of open longitudinal slots 35 and 36. In Fig. 5b is a blade element 8 is shown, which has an additional back 38, which has the shape of a 4-edge bar. Incidentally, the lamellar elements of FIGS. 5a and 5b are identical and each form a base module. Reference numeral 39 indicates that a multiplicity of lamellar elements can be pegged for an entire structural element. Web edges are designated by the reference numeral 34. These connect two slats 32nd

The lamellar element 8 as a basic element is profiled from solid boards from 1 to over 5 cm thickness, usually side goods of the species spruce, fir, beech, etc. on a four-side planer. The base module according to FIG. 5b has a spine 38 with, for example, a depth of 30 mm. This can be used for the Querverdübelung 39 of the slats, similar to a pegged Brettstapelbauweise. Thus, the composite is guaranteed purely mechanically, even without the use of glues. However, bonds based on emission-free silicate adhesives are also possible. Each fin element with e.g. 120 mm width (B) receives two-sided milling. The air cushions thus formed improve the λ-value of the solid wood or the U-value of the construction to λ = 0.064. A bionic analogy can thus be made to the bearskin, with the skin on the inside and the outward facing fur hair. The longitudinal slots 35, 36 create self-contained air chambers 40 (Figure 2) when inserted into a structural element, e.g. in a wall structure element or a frame or window kantel.

Fig. 6 shows examples of cross-sections with concrete measures of four different fin elements 8. The mass given may vary as desired within an economic order of magnitude. The basic character, however, is always the same. The two outstanding features are thin slats 32, or longitudinal slots 35, 36, which are produced by corresponding milled from both sides and the pronounced length «L» of a longitudinal profile. The width of the fin element 1 is indicated by B and the thickness by D of e.g. 20 mm to 36 mm, corresponding to the wide edges. For very particular applications, the grooves or longitudinal slots (35, 36) may be intermittently or only on a part of the length of the lamellae element, e.g. for door leaves. In special cases it is possible to manufacture lamellar elements made of plastic, especially if the lamellar element is used in a plastic environment, e.g. in plastic windows.

7a and 7b show two embodiments of plates or door leaves 70. A number of lamellar elements 8 are inserted between two shells 60, 61. At the top of a lipping 62 is shown with a fold 63. FIG. 7b has two shells 64, 65 and 66, 67 on both sides. These are door panels 70 as lightweight panels. The use is mainly for lightweight construction in house construction as interior doors or in container construction. The plates can also be used for partitions. The special feature here is that the plurality of lamellar elements 8 are used to increase the stability of the whole plate and less for thermal insulation.

The two FIGS. 8a and 8b show, in analogy to FIGS. 7a and 7b, a door leaf 70 as a horizontal section or cutout.

Figs. 9a and 9b show an example of a frame spread 68 for doors or windows. These are usually only individual elements. In both cases, a good thermal insulation is desired, therefore, the lamellar elements 8 are used analogously to the solutions according to FIGS. 1 to 3 with the largest possible number of closed air chambers in the Hauptwärmedämmrichtung. The lapping 62 lacks the fold according to FIGS. 7a and 7b and 8a and 8b.

In Fig. 10, a whole element is shown in the upper part of the picture as a frame widening 68 between the frame widening 68 and the window frame 13, a window frame 69 is shown.

Fig. 11 shows a section through a window as another example with a window frame 23 and window sash 5. With the solution shown, each of the window and frame scantlings is divided. It can be omitted in the window sash 5 separate glass rods, since the glass rods are part of the frame shells 10. Incidentally, the structure is analogous to FIGS. 1 and 3.

Claims (12)

1. wooden component or structural element with inserted lamellar element for the area of windows or doors with a plurality of longitudinally extending louvers, characterized by a box (37) or a box-like, closed structural element (19) and at least one lamella element inserted therein (8 ) with thin fins (32) and mutually spaced narrow slots (35, 36) which together and with the box (37) form a plurality of closed air chambers (40). 2. timber component according to claim 1, characterized in that the timber component (19) is designed as a door leaf (70), in particular for interior doors, wherein in the timber component (19) a plurality of lamellar elements (8) are glued, and together have a high stability , 3. timber component according to claim 1 or 2, characterized in that the box-like closed structural element (19) with a lipping (62) and as a single-layer or double-layered door leaf (70) is formed. 4. timber component according to one of claims 1 to 3, characterized in that the lamellar elements (8) in the door leaf (70) have a vertical orientation. 5. timber component according to one of claims 1 to 3, characterized in that the lamellar elements (8) in the door leaf (70) have a horizontal orientation. 6. timber component according to claim 1, characterized in that the structural element (19) with the lamellar element (8) for a good heat transfer coefficient (UFm) is formed, wherein the individual closed air chambers (40) have a rectangular cross-section, and the shorter dimension of Rectangular shape in the Hauptwäremmämmrichtung (28) is aligned and with the plurality of air chambers (40) results in a multiplied thermal insulation effect. 7. timber component according to claim 6, characterized in that the structural element (19) as a frame frame (10) is formed with each glued lamellar element (8). 8. timber component according to claim 6, characterized in that it is designed as a door or window frame, with comprehensive frame frame (10) or floor frame (24) with fitted plate elements (8). 9. timber component according to claim 6, characterized in that it is designed as a door or window frame or Stockrahmenverbreiterung (25). 10. timber component according to one of claims 1 to 6, characterized in that the lamellar element (8) has a plurality of in Holzfaserlängsrichtung parallel to the wide edges (41) and extending on both sides arranged rectangular or acute-angled grooves or louvers (35, 36), wherein the mutually arranged grooves (35, 36) are mutually staggered, and the lamellar element (8) with the forming plurality of thin lamellae, which are externally connected via webs (42), at least for short lamellar element patterns easily, "handorgelartig" deformable is. 11. lamellar element according to one of claims 1 to 10, characterized in that a lamellar element (8) is made of wood and preferably a width (B) of about 3 cm to 20 cm, particularly preferably in the range between 4 cm to 15 cm and a Length ("L") of 0.4 m to 5 m and a thickness of 1 cm to over 5 cm. 12. lamellar element according to one of claims 1 to 11, characterized in that the lamellae (32) of the lamellar elements (8) have a thickness (d), which is about the thickness (d) of the corresponding longitudinal slots or air slots ( 35, 36), wherein the thickness (d) of the fins and the corresponding air slot (35, 36) is preferably about 1-4 mm.